FR2962647A1 - DEVICE AND INSTALLATION FOR ASSEMBLING AT LEAST TWO MEDICINAL CAPSULES BY COLLAGE - Google Patents

Abstract

The device (1) according to the invention seeks to assemble at least two medicinal capsules (A, B) by gluing, reliably and economically, particularly in an industrial production context. To do this, this device comprises at least one matrix (10) adapted to elastically deform between a first configuration in which the matrix receives the capsules with an adhesive (Z) interposed between them, and a second configuration in which the matrix at least partially encloses the capsules to align and press against each other.

Description

The present invention relates to a device and an installation for assembling at least two medicinal capsules by gluing.

Throughout this document, the term "capsule" refers to a solid oral dosage form, consisting of a mixture of an active ingredient and excipients, adjuvants, vehicles and / or carriers. By solid oral dosage form is meant a solid oral administration form, that is to say a usual form suitable for administration such as orally. This includes in particular the forms of tablet, dragee, capsule or globule with flexible wall. This excludes a powdery or liquid composition that would not be included in a solid oral dosage form. By WO-A-2009/092819, one of the cotitulaires of the present proposed to combine several drugs in different solid dosage forms respectively, into a single solid dosage form. An embodiment envisaged for this meeting consists of an assembly of these several drugs by gluing. Such a galenic form, resulting from the gluing of several galenic elements, presents significant interests with regard to the problem of the observation of the medicinal treatments. These interests are set forth in detail in WO-A-2009/092819, so that the reader can refer to them for further details.

The object of the present invention is to provide means for obtaining such an assembly of several galenic elements, which are reliable and economical, particularly in a context of industrial production. For this purpose, the subject of the invention is a device for assembling at least two medicinal capsules by gluing, characterized in that it comprises at least one matrix adapted to elastically deform between a first configuration in which the matrix receives the capsules with an adhesive interposed between them, and a second configuration in which the matrix at least partially encloses the capsules to align and press against each other. The idea underlying the invention is to use a flexible matrix to receive, center and tighten at least two separate pre-existing capsules, between which glue has been deposited. The flexibility of the matrix according to the invention is such that it can be deformed between two extreme configurations: in one of these two configurations, the matrix largely opens to the capsules to assemble the access to a receiving housing that it delimits and which is advantageously shaped to impose a predetermined relative positioning between the tablets, somehow by stacking them, while, in its other extreme configuration, the matrix is deformed so that the wall of its aforementioned housing matches more the capsules present , to produce on them, by complementarity of shapes, a relative clamping to compress the adhesive interposed between them and thus bind them firmly. In practice, the flexible matrix according to the invention is in various models and embodiments, as described in detail below. In any case, the fact of using such a flexible matrix to handle the capsules and accompany their bonding makes it possible to reach high production rates, typically of several thousand articles per hour, with efficient, reliable and reliable material means. respectful of the health and safety constraints of the pharmaceutical industry. In particular, the action of the matrix to align and tighten the capsules is gentle in the sense that it does not damage these capsules. In addition, the matrix according to the invention is easily washable, especially dry. Moreover, within the limits of its elastic deformation capabilities, the same matrix can be used to assemble two or more capsules with different geometries and / or dimensions.

In other words, the use of the matrix according to the invention is modular and therefore economical. According to advantageous features of the assembly device according to the invention, taken individually or in any technically possible combination: the die is adapted to pass from its first to its second configuration under the action of a pneumatic pressure; the matrix delimits, at least partially, both a housing for depositing the capsules and an inflatable chamber, this housing and this chamber being separated from each other by a deformable wall of the matrix, which, by flexible deformation at least partially enveloping the capsules when the chamber is inflated to pass the matrix from its first to its second configuration; the housing has a concave bottom for centering the capsules, which is delimited by the matrix, and, when the matrix is in its first configuration, the deformable wall has, on the housing side, a substantially frustoconical surface converging toward the bottom of the housing; ; - The device comprises a rigid insert for receiving and wedging of one of the capsules, which is arranged in a base of the matrix, from which the deformable wall extends, and which forms a bottom for the housing; the deformable wall has a greater capacity for flexible deformation than the rest of the matrix, which, for this purpose, is for example surrounded by a stiffener and / or has a greater thickness and / or is held in place by the insert; the device comprises both a matrix fixing support, which defines an inflation passage of the chamber, and a pneumatic distribution plate, on which the fixing support is mounted and which jointly feeds several inflation passages opening into the chamber; respective chambers delimited either by as many individual matrices or by a common matrix; the pneumatic distribution plate also feeds at least one blown duct of the glued capsules, which opens into each housing. The subject of the invention is also an installation for assembling at least two medicinal capsules by gluing, characterized in that it comprises: at least one assembly device as defined above, first means for providing a first of the capsules to be assembled to the matrix of the device while this matrix is in its first configuration, - second means for providing a second of the capsules to be assembled to the matrix of the device while this matrix is in its first configuration, means for applying an adhesive to the capsule or capsules received by the matrix of the device while this matrix is in its first configuration, relative drive means between, on the one hand, the device and, secondly, the first means, the second means and the application means, and - control means, including pneumatic control, to pass the matrix between its first and second config urations. According to an advantageous implementation of this installation, the relative drive means are adapted both to place the matrix accessible from above for the capsules provided by the first and second means, as well as for the glue applied by the application means, and to turn the matrix down, firstly, after the control means have passed this matrix from its first to its second configuration and, secondly, before the control means pass this matrix from its second to its first configuration. The invention will be better understood on reading the description which follows, given solely by way of example and with reference to the drawings in which: FIG. 1 is a schematic section of a device according to a first embodiment according to the invention; FIG. 2 is a view similar to FIG. 1, illustrating the device in a different service configuration from that of FIG. 1; - Figure 3 is a schematic elevational view of an installation according to the invention, including the device of Figure 1; Figure 4 is a schematic elevational view along the arrow IV of Figure 3, Figure 5 is an exploded perspective view of a second embodiment of a device according to the invention; and Figure 6 is a section in the plane V of Figure 5, in the assembled state of the device. FIG. 1 shows a device 1 making it possible to bond one or the other by bonding at least two medicinal capsules A and B. In the example shown in the figures, the capsules A and B have respective respective geometries. identical, namely those of a disc having a convex main face while the opposite main face is at least partly flat to form between the capsules A and B a flat contact interface, with interposition of a Z-shaped glue 'a diaper. It is emphasized here that the respective geometrical shapes of the capsules A and B are not limiting of the present invention, in the sense that other geometries than those shown in the figures are conceivable for these capsules, being moreover noted that, according to In these cases, the capsules A and B may have respective different geometries from each other, as long as the forms retained can establish between them a contact interface where a sufficient quantity of the adhesive Z is attached to firmly bind the to each other the capsules A and B.

As clearly visible in FIG. 1, the device 1 comprises a matrix 10 designed to receive the capsules A and B. More specifically, this matrix 10 comprises, or even consists of a body 11, which is monoblock in the example considered in the figures and which is made of a flexible material, that is to say a material capable of elastically deforming. In practice, the material constituting the body 11 of the matrix 10 is chosen to respect the health and safety constraints of the pharmaceutical industry, in the sense that this material can be brought into contact with the drug capsules A and B without risk to the subsequent consumer health of these capsules. In particular, this material complies with the requirements of the US Food and Drug Administration. For example, this material is silicone or silicone-based. The body 11 of the die 10 comprises a central base 12, centered on an axis X-X, being produced here in the form of a cylinder with a circular base. The body 11 also comprises a lateral peripheral wall 13, centered on the axis X-X, being here produced in a tubular form with a circular base. The central base 12 and the side wall 13 are connected to one another by a thin transverse wall 14 belonging to the body 11, which extends from the periphery of one of the axial ends of the base 12 to at one of the axial ends of the wall 13, running around the axis XX. In this way, the base 12 and the wall 14 jointly delimit a housing 15 in which the capsules A and B can be deposited, as shown in FIG.

Advantageously, the bottom 151 of the housing 15, which is delimited by the axial end of the base 12, is concave, being centered on the axis XX, in order to force the centering on the axis XX of the capsules A and B by sliding effect against this bottom 151. Advantageously, the bottom 151 at least partially marries the capsule. In addition, on its side facing the housing 15, the wall 14 advantageously has a frustoconical surface 152, centered on the axis XX and converging towards the bottom 151 of the housing 15. At the same time, the base 12, the wall side 13 and the wall 14 jointly define, on the side of the wall 14 opposite the housing 15, a chamber 16 which runs around the axis XX, surrounding the housing 15. In the embodiment considered here, this chamber 16 has a substantially annular geometry, centered on the axis XX. In practice, the embodiment of the housing 15 and the chamber 16 within the matrix 10 is in particular obtained by adequate molding of the body 11, the mold required for its molding being simple and economical to manufacture. In addition, the device 1 comprises a support 20 for fixing the matrix 10. In the embodiment considered here, this support 20 is made in the form of a rigid plate, for example a metal plate or a plastic plate, whose face facing the die 10 has complementary receiving cavities of the respective axial ends of the base 12 and the side wall 13, opposite their axial end connected by the wall 14. A screw 21 is attached through the support plate 20, coaxially with the base 12, to engage a metal insert 22 embedded in the base 12, as clearly visible in Figure 1. The support plate 20 is also traversed from one side by a free passage 23 which, at one of its ends, opens into the chamber 16, while its opposite end opens into a pneumatic distribution duct 24 delimited by a rigid plate 25, for example metal or in plastic material, on which is mounted the support plate 20. In use, the aforementioned conduit 24 is connected to a pneumatic source, not shown, preferably a source of compressed air. In this way, when the aforementioned source feeds the conduit 24 with compressed air, the latter flows through the passage 23, as indicated by the arrows 26 in FIG. 2, to reach the chamber 16, thereby causing the pressure to increase. internal of this room. As represented in FIG. 2, under the action of this pneumatic pressure, the chamber 16 inflates, by means of the flexible deformation of the matrix 10, more particularly of the wall 14 of its body 11. In other words, the matrix 10 passes through an undistorted configuration of its body 11, shown in Figure 1, in which the housing 15 has, opposite its bottom 151, an opening large enough for the capsules A and B to access the interior of this housing, to a deformed configuration of its body 11, shown in Figure 2, wherein the wall 14 is elastically deformed to one side of the wall 14, to expand inflation of the chamber 16 and, on the side opposite, allow the constriction of the housing 15, as indicated by the arrows 27 in Figure 2. With regard to the presence of the capsules A and B in the bottom region of the housing 15, the wall 14 is in the configuration of Figure 2, deformed at least partially marrying the capsules so as to tighten them against each other, by pressing between them the adhesive Z. It is understood that, due to the flexible and progressive deformation of the wall 14 when the matrix 10 passes from its configuration of Figure 1 to its configuration of Figure 2, the capsules A and B are gradually clamped, from top to bottom, between the wall 14 and the bottom 151 of the housing 15, which has the effect of aligning the capsules A and B along the axis XX, then to apply a relative pressing between them while maintaining their arrangement aligned. In practice, to control the progressive deformation of the wall 14, by accentuating first its deformation at the flared end of the housing 15, then propagating this deformation towards the housing floor 151, we can play on a variation The fact of controlling the passage of the matrix 10 from its configuration of FIG. 1 to its configuration of FIG. 2 under the action of a pneumatic pressure has the additional advantage that, in case puncture of the inflation chamber 16, the body 11 remains in the undeformed position. Moreover, the use of clean and dry compressed air to inflate the chamber 16 is an economical solution in the sense that sources of compressed air are widely available. In order to concentrate on the wall 14 the action of the pneumatic pressure prevailing in the inflated chamber 16, the device 1 advantageously comprises a stiffener 28 coaxially surrounding the lateral wall 13, as represented in FIGS. 1 and 2. In practice, this stiffener 28 is fixed on a plate 29 mounted on the support plate 20 and participating in the attachment of the matrix 10 to the support plate. FIGS. 3 and 4 show an installation comprising several devices 1 mounted on a conveyor 30. More specifically, each device 1 of this installation includes a plurality of matrices 10 described individually with reference to FIGS. 1 and 2, these matrices being all supported by the same plate 20, itself mounted on the pneumatic distribution plate 25 whose conduit 24 jointly feeds as many passages 23 as matrices 10. The matrices 10 of each of these devices 1 are thus distributed one after the other. other, in the longitudinal direction of the plates 20 and 25, as clearly visible in Figure 3. As an alternative not shown, rather than providing individual matrices 10 as described just above, a single matrix can be provided to extend over the entire length of the plates 20 and 25, this single matrix delimiting then, distributed according to its directio n longitudinal, several housing 15 each associated with an inflatable chamber 16. In all cases, when the device 1 is observed in the direction of the axis XX as in Figure 3, this device has a rectilinear succession of housing 15. The conveyor 30 comprises one or, as shown here, several strips 31 for driving the devices 1, wound around a motor cake 32 and, on the opposite side, a drum 33 (FIG. 4). By actuation of the cake 32, the strips 31 drive the devices 1 which are distributed along the driving direction of these strips: in this way, when the installation is in use, the dies 10 of each device 1 are cyclically turned towards the machine. up and downwards depending on the winding position of the strips 31 around the cake 32 and the drum 33, as can be seen in FIG. 4.

The installation of Figures 3 and 4 also comprises several functional stations, distributed around the conveyor 30 and acting on the device 1 at their respective level, as detailed below. Thus, a first station 40 is provided for depositing in each housing 15 of the device 1 located at this station, while the matrix or matrices 10 of this device are in their undeformed configuration of Figure 1, a medicinal capsule A from of a corresponding reserve of these capsules. Advantageously, this station 40 deposits the capsules A in the device 1 by gravitational action. In other words, each capsule A falls inside one of the housings 15, being guided to the bottom 151 of this housing by the frustoconical surface 152 of the housing.

In the exemplary embodiment considered in FIGS. 3 and 4, this station 40 comprises a vibratory bowl 41 containing the reserve of capsules A, a ramp 42 for positioning the capsules A, fed in capsules by the vibratory bowl 41, as well as a slide 43 for gripping the capsules A positioned by the ramp 42. Preferably, the slideway 43 is designed to take the capsules A from the ramp 42 by means of a suction system which, once the slideway 43 is moved to the Plumb with the device 1 located at the station 40, as shown in Figure 3, releases the tablets A which then fall by gravity in the housing 15 or the matrix 10 of this device. The installation of FIGS. 3 and 4 also comprises a station 50 functionally similar to the station 40, but making it possible to deposit in each housing 15 of the matrix or matrices 10 of the device 1 located at this station 50, not a capsule A, but in practice, the station 50 has the same elements as the station 40, namely a vibrating bowl 51, a ramp 52 for positioning the capsules B, and a gripping slide 53, being noted that, in the figure 3, unlike the slideway 43 which is shown in its position in line with one of the devices 1, the slideway 53 is shown during cooperation with the positioning ramp 52. Between the stations 40 and 50 following the the driving direction of the devices 1 by the conveyor 30, the installation of FIGS. 3 and 4 comprises a station 60 for applying the glue Z. Preferably, this station 60 includes a gravitational release system of glue drops, especially pa r microdosing, thus allowing a drop of glue Z to fall into each housing 15 of the matrix or matrices 10 of the device 1 located at the station 60. In practice, with regard to the positioning of the station 60 relative to the station 40, the The aforementioned drop of Z adhesive falls on the capsule A which has been previously deposited in each of the housings 15, when the device 1 was at the station 40. As an advantageous option, the installation of FIGS. station 70 which, in the direction of driving of the devices 1 by the conveyor 30, is located between the stations 40 and 60 and which makes it possible to detect the presence of a capsule A in each of the housings 15 of the matrix or matrices 10 of the device 1 located at this station 70. In the absence of one or more capsules A, the station 70 is designed to warn an operator to proceed to corrective actions, or even automatically apply such actions: by ex For example, the station 70 can then control the downstream station 60 to inhibit the application of glue to the device 1 concerned. In use, the conveyor 30 moves the devices 1 successively at the stations 40, 70, 60 and 50, it being specified that the matrices 10 of the devices 1 located at these different stations are in their undistorted configuration of FIG. 1. Then, after displacement by the conveyor 30 of the device 1 situated at the station 50, control means, not shown in the figures, are actuated to pass the matrix or matrices 10 of this device 1 from their undeformed position of the FIG. 1 to their deformed position of Figure 2: the capsules A and B present in this or these matrix 10 are contained by the body 11 of this or these matrices, as explained above with reference to Figure 2. The control means The aforementioned and maintain the die or matrices 10 of the device 1 in their deformed configuration while the conveyor 30 moves the device 1 to place the latter at the base of a recovery station ion 80, the matrix or matrices 10 of this device 1 then being turned downwards. The time required for the device 1 to be conveyed from the station 50 to the station 80 is thus used to dry the adhesive Z interposed between the capsules A and B present in the housing 15 of the device 1. In other words, the conveyor sector 30 extending between the stations 50 and 80 corresponds to a drying sector of the adhesive Z. At the recovery station 80, the aforementioned control means are deactivated, that is to say that, by elastic return and / or forced deflation, the body 11 of the or each die 10 of the device 1 passes from its deformed configuration of Figure 2 to its undistorted configuration of Figure 1: the capsules A and B glued to one another fall then in a pavilion 81 of the recovery station 80, at the output of which the glued capsules are conveyed to a storage container 82.

As an advantageous option, the installation of FIGS. 3 and 4 further comprises a washing station 90 (FIG. 4) making it possible to wash, in particular dry, the housings 15 of the matrix or matrices 10 of the device 1 situated at the level of FIG. of this station 90. In practice, the washing station 90 is located, in the driving direction of the devices 1 by the conveyor 30, between the recovery station 80 and the station 40 of removal of the capsule A.

Thus, the devices 1 integrated in the installation of Figures 3 and 4 can be assembled by gluing the capsules A and B reliably and economically, while allowing high production rates. In Figures 5 and 6 is shown an alternative embodiment of the device 1, referenced 1 '. This device 1 'can in particular be integrated in the installation of Figures 3 and 4, instead of each of the devices 1. Hereinafter, will be presented in more detail the differences between the devices 1 and 1', being understood that the components of the device 1 ', functionally similar to the components of the device 1, bear the same references as the latter, followed by "'". Thus, the device 1 'has a plurality of dies 10' supported by the same plate 20 ', which is itself mounted on a pneumatic distribution plate 25' and which is assembled a plate 29 'for fixing the dies. Each die 10 'consists of a flexible body 11' including a central base 12 'and a lateral peripheral wall 13', and a deformable transverse wall 14 'connecting them to each other, all three centered on a axis XX.

In the same way as the plate 25, the plate 25 'is designed to be fixed on the conveyor 30 or on a similar conveyor, typically using screws referenced 34' in FIG. 5. In a manner similar to the device 1, each die 10 'of the device 1' defines an inflatable chamber 16 'into which a passage 23' through the support plate 20 'opens. This passage 23 'thus connects the chamber 16' to a pneumatic distribution duct 24 'delimited in the plate 25'. Unlike the device 1, the fixing of each die 10 'to the support plate 20' is partly achieved by a rigid insert 22 'which is screwed into the support plate 20' from the face of the latter facing the matrix 10 '. To do this, the base 12 'of each die 10' has, over its entire axial dimension, a tubular shape centered on the X-X axis and open at both ends. At its end facing the support plate 20 ', the tubular base 12' opens onto a thread for receiving a threaded portion of the insert 22 'provided in the plate 20'. Thus, by introducing, along the axis XX, the insert 22 'successively inside the wall 14' and the base 12 ', this insert is attached and screwed to the support plate 20' , occupying the internal volume of the base 12 '. In this way, this insert 22 'forms a bottom wall for the housing 15' for depositing capsules A 'and B' to be bonded, delimited internally by the wall 14 '.

A first interest in this arrangement lies in the fact that the insert 22 'stiffens the base 12', thus maintaining in place the latter. A second interest is related to the fact that this insert 22 'is advantageously shaped to receive and wedge the capsule A' deposited first in the matrix 10 ', marrying at least partially this capsule A'. Thus, in the exemplary embodiment considered in FIGS. 5 and 6, each insert 22 defines an elongated cavity 22'1, centered on the axis XX and opening into the housing 15 ', in order to receive in a complementary manner the essential of the capsule A 'which corresponds here to a capsule. In use, the device 1 'is used in the same way as the device 1. In particular, when the chamber 16' of each matrix 10 'is inflated by compressed air supplied by the conduit 24', the wall 14 from its undeformed configuration, represented in solid lines in FIG. 6, to a deformed configuration, represented in phantom in FIG. 6 and in which this wall aligns and then presses the capsule B ', which is here akin to a compressed, against the capsule A ', squeezing between these capsules glue Z'.

A third interest related to the insert 22 'concerns the possibility of facilitating the release of the capsules A' and B 'after their bonding. To do this, as clearly visible in FIG. 6, the insert 22 'delimits internally a through channel 22' 2, which is centered on the axis XX and which connects its cavity 22 '1 to a pneumatic distribution duct 24' '. defined by the plate 25 'This duct 24 "is distinct from the duct 24', being sealed with respect thereto by a flat gasket 25" attached between the plates 20 'and 25'. that the capsules A 'and B' have been glued to each other, by supplying compressed air to the duct 24 ', ensuring the inflation of the chamber 16', the supply of the duct 24 'is interrupted at advantage of the duct 24 ": pressurized air then flows through the channel 22'2 of the insert 22 'of each of the dies 10', into the housing 15 ', to eject by blowing the glued capsules A' and B'.

Various arrangements and variants devices 1 and 1 ', and the installation of Figures 3 and 4 are also possible. By way of example: to facilitate the release of the glued capsules A and B with respect to the matrix, a capsule blowing channel, functionally similar to the channel 22'2 described with reference to FIG. be provided through the base 12; at one of its ends, this blowing duct opens directly into the bottom 151 of the housing 15, while its opposite end is connected, via the plates 20 and 25 arranged accordingly, to a compressed air circuit distinct from that feeding the chamber 16; rather than being controlled by a pressure, the passage of the matrix 10 or 10 'between its undeformed and deformed configurations can be obtained by a depression, that is to say by suction of air; - By varying the thickness of the side wall 13, the stiffener 28 can be removed, as is the case for the device 1 '; - The recovery station 80 may advantageously include means for sorting the glued capsules that it processes, so as to separate the presumed good products and capsules considered poorly bonded or non-compliant; the shape of the matrix 10 or 10 'is not limited to that shown in the figures; likewise other embodiments that the components 20, 21, 22, 25 and 29 or 20 ', 22', 25 'and 29' are conceivable for the mounting and the pneumatic control of this matrix; the number of capsules that the device 1 or 1 'can assemble to one another by gluing is not limited to two; on the contrary, three or four or more capsules can be glued to each other through the device 1, as long as each housing 15 or 15 'of the matrix or matrices 10 or 10' is dimensioned accordingly; in this case, the installation of Figures 3 and 4 is completed by as many positions as necessary, as indicated for example in dashed lines in Figures 3 and 4: in the direction of movement of the devices 1 by the conveyor 30, there is so planned between

12 stations 50 and 80, on the one hand, the succession of a detection station 170, a glue application station 160 and a station 150 for depositing a third capsule, which are functionally similar to the stations 70, 60 and 50, then, on the other hand, the succession of a detection station 270, an adhesive application station 260 and a station 250 for depositing a fourth capsule, which are they also functionally similar to stations 70, 60 and 50; and / or the arrangement around the devices of the stations 40, 50, 60 and 70, as well as, if appropriate, the stations 150, 160, 170, 250, 260 and 270 is not limited to that shown in FIG. 3; for example, for reasons of space, all these stations can be arranged on one and the same side of the conveyor 30.

Claims (1)

1. A device (1; 1 ') for assembling at least two medicinal capsules (A, B; A', B ') by gluing, characterized in that it comprises at least one matrix (10; 10'). ) adapted to elastically deform between a first configuration in which the matrix receives the capsules with an adhesive (Z; Z ') interposed between them, and a second configuration in which the matrix at least partially encloses the capsules to align them and press them against each other. 2.- Device according to claim 1, characterized in that the matrix (10; 10 ') is adapted to move from its first to its second configuration under the action of a pneumatic pressure. 3.- Device according to one of claims 1 or 2, characterized in that the matrix (10; 10 ') delimits, at least partially, both a housing (15; 15') for depositing the capsules (A, B; A ', B') and an inflatable chamber (16; 16 '), this housing and this chamber being separated from each other by a deformable wall (14; 14') of the matrix, which by flexible deformation, at least partially envelopes the capsules when the chamber is inflated to pass the matrix from its first to its second configuration. 4.- Device according to claim 3, characterized in that the housing (15) has a concave bottom (151) for centering the capsules (A, B), which is delimited by the matrix (10), and in that, when the matrix is in its first configuration, the deformable wall (14) has, on the housing side, a substantially frustoconical surface (152) converging towards the bottom of the housing. 5.- Device according to one of claims 3 or 4, characterized in that it comprises a rigid insert (22 ') for receiving and wedging one of the capsules (A'), which is arranged in a base ( 12 ') of the matrix (10'), from which the deformable wall (14) extends, and which forms a bottom for the housing (15 '). 6.- Device according to any one of claims 3 to 5, characterized in that the deformable wall (14; 14 ') has a larger flexible deformation capacity than the rest of the matrix (10; 10'), which for this purpose, for example, is surrounded by a stiffener (28) and / or has a greater thickness and / or is held in place by the insert (22 '). 7.- Device according to any one of claims 3 to 6, characterized in that it comprises both a support (20; 20 ') for fixing the matrix (10; 10'), which delimits a passage ( 23; 23 ') for inflating the chamber (16; 16'), and a pneumatic distribution plate (25; 25 '), on which the fixing support (20; 20') is mounted and which feeds several passages together. inflation means (23; 23 ') opening into respective chambers (16; 16') delimited either by as many individual matrices (10; 10 ') or by a common matrix. 8.- Device according to claim 7, characterized in that the pneumatic distribution plate (25 ') also feeds at least one channel (22'2) blowing the glued capsules (A', B '), which opens in each housing (15 '). 9.- Installation assembly of at least two drug capsules (A, B; A ', B') by gluing, characterized in that it comprises: - at least one assembly device (1; 1 ') according to any one of the preceding claims, - first means (40) for supplying a first of the capsules to be assembled (A; A ') to the matrix (10; 10') of the device whereas this matrix is in its first configuration, - second means (50) for supplying a second of the capsules to be assembled (B; B ') to the matrix of the device while this matrix is in its first configuration, - means (60) for applying a glue (Z; Z ') on the capsule or capsules received by the matrix of the device while this matrix is in its first configuration, - means (30) relative drive between, on the one hand, the device (1; 1 ') and, on the other hand, the first means (40), the second means (50) and the application means (60), and - means of e control, including pneumatic control, to pass the matrix (10; 10 ') between its first and second configurations. 10.- Installation according to claim 9, characterized in that the relative drive means (30) are adapted both to place the matrix (10; 10 ') accessible from above for the capsules (A, B A ', B') provided by the first and second means (40, 50), as well as for the glue (Z; Z ') applied by the applying means (60), and for turning the die downwards; on the one hand, after the control means have passed this matrix from its first to its second configuration and, on the other hand, before the control means pass this matrix of its second to its first configuration.